Converting plural-element information



y 13, 1965 H. GEBHARDT 3,195,124

CONVERTING PLURAL-ELEMENT INFORMATION Filed Feb. 12, 1962 4 Sheets-Sheet 1 July 13, 1965 H. GEBHARDT CONVERTING PLURAL-ELEMENT INFORMATION 4 Sheets-Sheet 2 Filed Feb. 12, 1962 July 13, 1965 H. GEBHARDT 3,195,124

CONVERTING PLURAL-ELEMENT INFORMATION Filed Feb. 12, 1962 4 Sheets-Sheet 3 Fig.3 (H) (s) 1 um 10 10 M9 a 1 1 a l 0, @522 I,

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v K v 001/ 42 I 007/42 Q 5 mo July 13, 1965 H. GEBHARDT 3,195,124

CONVERTING PLURAL-ELEMENT INFORMATION Filed Feb. 12, 1962 4 Sheets-Sheet 4 Fig.5

[1 T r t SPU BuC ZlC 10 Vs! s o Sch2 Sch1 I! B n United States Patent 3,31%,124 CGNVERTHNG PLUdAL-ELEMENT TNFQRMATKBN Hartmut Gehhardt, Gresshesselohe, near Munich, Germany, assignor to Siemens & Eialske Aktiengesellsehatt, Berlin and Munich, a German corporation Filed Feb. 12, 1962, Ser. No. 172,585 Claims priority, application Germany, Feb. 17, 1963, S 72,586 8 Claims. (Cl. 340-347) The invention disclosed herein is concerned with the conversion of information consisting of a plurality of individual elements.

It is known to select from a matrix a magnetic core representing the result of a plurality of individual informations. In such procedure, which is among others applied in binary adding and subtracting, there is provided a winding for the transmitter as well as for each of the two values which are to be respectively added or subjected to subtraction. These windings are connected in parallel with a further winding serving for the extension of a timing pulse and with a winding provided for restoring all magnetic cores in the pause between two calculating operations. Such an arrangement is limited with respect to the number of input windings since the tolerances of the individual circuits have to be considered.

There is known a multiple AND circuit, for the conversion of information items with magnetic cores, which operates according to the 1/2 principle. In this known solution, however, high demands are made with respect to operation precision involving current and temperature. A reduction of the current in one or in both cases leads to a mutilation of information, since the selected core is only partially demagnetized. Likewise, in the case of excessively great currents a large number of cores (x-f-y column) are demagnetized, although only one core should be involved. At low or high temperatures there takes place at uniform current, in this known switching arrangement, likewise, either only a partial demagnetization of the result core or a multiple feeding in (ac-{- 1 column). These changes occasioned by the temperature are due to alternation of the hysteresis loop.

The invention has as its object the development of a switching arrangement for the conversion of a first in formation item into a second information item with magnetic cores, in which system the current and temperature tolerances in each core compensate themselves. This problem is solved in which, with more than one basis of selection, one core of m cores is selected, whose control lines are collected in groups and in the group the individual writing lines lie in series with selector switches by an arrangement wherein the series switching circuits of these stages lie in series with a blocking wire conducted through all the cores, which wire passes (x1) time through each core in a direction opposite to that of the writing wires.

Upon closing of the switch there results an individual current circuit running over x writing wires and the blocking wire, which circuit, in consequence of corresponding conduction of the writing wires run through a single one of, for example, n cores x times and in consequence of the counterexcitation through the blocking wires can demagnetize only the one core, to which the second information item is allocated. With a switching arrangement according to the invention the drawbacks of the known arrangement, are eliminated and the current and core tolerances are to a large degree compensated.

Circuit arrangements according to the invention are required, for example, in connection with electronically operating calculating and accounting machines, wherein the input values are to be converted into values with which the machine can operate. An application of such arrangement is however also of advantage in connection with the automatic distribution of mail, wherein a destination criterion is to be formed, for example, from a plurality of characters selected according to a given principle from the name of a place of destination of given items.

it may however happen that a second information cannot be definitely obtained, based upon the input of a first information. This is, for example, the case in connection with a booking machine for air travel involving routes which are serviced by several air lines. In accordance with another feature of the invention, there is provided an auxiliary readout wire upon all magnet cores to which no definite result is assigned. All these readout wires are serially circuited and extended to a control readout amplifier. The output impulse of this control readout amplifier indicates at an operator position the request for a supplemental input, stores the result so far obtained, and prepares the circuit arrangement of the receipt of an auxiliary criterion. Accordingly, it will be necessary to supply only as many informations as are as a rule required for obtaining a definite result and to indicate the need for further information only when it is required.

Further features of the invention are defined in the appended claims and will be brought out in the description which will be rendered below with reference to the accompanying drawings which illustrate the invention in connection with an example of an embodiment of a converter for mail distributing installation.

PEG. 1 shows the arrangement of a storage matrix of a series-parallel converter;

FIG. 2 represents the switches with the encoding r riting wires 5 and 'y a nd the blocking wires El;

FIG. 3 indicates the character encoding field with successively disposed amplifier groups;

PEG. 4 illustrates the numeral encoding field with successively disposed amplifier groups; and

FIG. 5 is a block circuit diagram of the arran ement.

The converter underlying the illustrated embodiment is assumed to be connected to an individual encoding station or position for the purpose of ascertaining criteria for incoming mail. It is thereby necessary to produce a code from a given selection of characters included in a street designation, such code corresponding to the mail man who delivers the mail. However, since there are streets which are serviced by several mail men, the house numbers must also be supplied so as to obtain definite unequivocal results. The operating principles of the converter will therefore be explained in connection with an example of the encoding of a street which is located within the delivery rea of a single mail man, and also in connection with an example of the encoding of :a street which is located within the delivery areas of several mail men.

The representation appearing in the drawings shall first be briefly discussed before explaining the operation of installation.

The entry of the individual information is effected with the aid of a key board ET (FIG. 1) comprising contacts T1 to T2t In order to simplify the equipment, the seriesparallel converter has been designed for character encoding as well as for number encoding, resulting in the parallel connection of the contacts of the entry keys as shown in FIG. 1. The key for the character A is associated with the key for the number 0 and the character key D is similarly associated with the number key 3. The character key I is additionally connected in parallel with the character key D since only twenty contact combinations are used for forming the character combination from the twenty six characters of the alphabet, thus requiring combining of the excess characters with other characters. For example, the character key D is inthis manner placed together with the character I and the character W is placed together with the character X. The same converter serves for the characters as well as for the numbers, and the same a ending amplifiers serve likewise for the characteras well as for the n ber-encoding field.

The core matrix shown in FIG. 1 comprises four lines or rows and twenty columns and a four-stage electronic stepping device having the switching stages S154. Each of the cores tar-rise is operatively connected to switches, for example, electronic switches such as transistors, in which case each or" the cores may carry the base win of a respectively cooperatively disposed switching transister, the corresponding arrangement being indicated in H6. 2.

One side of each of the twenty switches, for example, the emitters of switching transistors of the first row lie on the positive terminal of a current source B while the other side thereof, such as the collectors are connected, over the encoding-field writing wires snare, with each one side of the twenty switches, for example, the emitters oi the switching transistors of the second row. The switches of the second row are likewise connected, over the encodingwriting wires (tillth, with the twenty switches of the third row. The transition from the third to th fourth row follows the same scheme. The switching circuit extends from the fourth row, with its encodingfield writing wires Mil-68d, over the blocking wires Bil, B52; and the impulse switch Schl to the negative terminal of the current source 13.

The switches of the reading amplifier, for example, also Witching transistors, with their writing cores 7 are indicated within the dash line rectangle in the bottom part of PEG. 2.

FTG. 3 shows in schematic manner the character encoding field BuC. To each combination result is in this field assigned a magnet core which triggers the end result. The magnetization of this core is in the present example changed to the 1 condition only when four writing wires assigned to this character act on the core, each with +ll change of magnetization current. A blocking wire Bil acting at the writing instant with -31 on each core of the encoding field prevents change of magnetization of a core unless all four writing terms are effective.

The cores of the character encoding field carry in addition to the Writing wires 5 and the blocking wire Ell, a readout wire Abfr and two sensing or reading wires Ct.

All sensing or reading wires or of the same number of a tens power are in the encoding field serially connected extended to one of the 2 10 sensing or reading amplifiers the output of which is characteristic for the respective number. The end result is extended to an encoder C0.

The number encoding field Zz'C shown in FIG. 4 is constructed similarly as the character encoding field Bar). To each switching core are assigned four sensing or reading wires 5, two writing wires 7, a blocking wire B52, a readout wire Abfr, and two sensing or reading wires or. The sensing or reading wires are here likewise serially disposed and extend to reading amplifiers Vst.

The arrangement according to the invention shall as certain, from four characters successively fed thereto, which are taken from street names, the number of a mail man, in the present case a number from 1 to 96, who delivers mail within an area which includes the addressee of a mailed item. The number which is ascertained by the conversion is printed on the respective mailed item, for example, in coded form, with magneticink, and such item, for example, a letter, is fed to a letter sorting machine which in turn feeds the letter according to the printed information to the container reserved for the mail man who delivers mail in the respective territory.

The operation of the arrangement according to th present invention shall first be explained in connection with the coding of a street which is located in the delivery territory of a single mail man. The street name Hedwig Street shall serve as a coding example, the code characters selected from this street name being assumed to be the characters HDWG. The street involved is located within the delivery territory of a mail man to whom is assigned the number 49.

The switch S1 (FIG. 1) is at the start of an input cycle always closed, while the switches 82-84 are open. The four characters are by a code operator successively keyed in the eyboard ET. Depression of the key H closes the contact TS, thereby causing the writing wire extending from the contact T8 jointly with the writing wire extending from the switch S1, to change the magnetization of the core K3, according to the J/2-principle, to the l-condition. After keying the first character (H), the switch ST is opened and switch S2 is closed, and the core. K24 is placed into the l-condition responsive to depression of the key D denoted by the second character D. The magnetization of the core K is thereupon similarly changed responsive to the keying of the third character W by means or" the key W. Keying of the fourth character G of this input cycle, by means of the key G places the core K67 into the 1. condition. Four of the cores, one core in each row or line of the core matrix are in this manner marked, such marked cores being indicated in solid black so as to recognize them at a glance. This marking ma be referred to as the first information which is'to be converted into a second information in the manner described below.

be input writing operation in the character encoding field BuC (FIG. 3) is initiated upon effecting change of magnetization of the cores KS, K24, K59 and K67 (FIG. 1) into the 1-condition, thereby concluding the series input feeding of the characters HDWG into the matrix. All of the cores of the matrix are now read out. Only the cores which had been placed into the 1-conditionwill upon restoration thereof into the 0-condition supply a voltage, over their respective base windings, to the bases oi switching transistors respectively assigned thereto (FIG. 2) whereby one switching transistor per line becomes conductive, thus connecting through, for a few milliseconds, a circuit over the writing wires 58, 624, 66th, 867 in the character encoding field (FIG. 3), such circuit being characteristic for the character combination HDWG and extending over the switching transistor Schl (FIG. 2). This circuit affects all cores in the encoding field, the character combination of which has in the first place an H, in the second place a D, in the third place a W, and in the fourth place a G. Only one of the many cores which are affected in this circuit contains all four input terms, namely, the core Klill (FIG. 3), and such core is accordingly changed in magnetization while all other cores, for example, the core K162, cannot be changed in magnetization, into the l-condition owing to the effect exerted by the blocking wire Bll.

As is apparent from FIG. 2, the activated Writing wires are over their switching transistors serially connected and are always included in the same circuit with the blocking wire B/l which is disposed between the points a and b.

Upon reading out the core Kllll which is in the assumed example operatively affected, there is produced a reading voltage in the reading Wires all and 052, which voltage is amplified by the amplifier of the order 4X10 and by the amplifier of the order 9x10 Each of the amplified reading signals magnetizes a storage core (not shown), which is respectively assigned to each reading amplifier, into the l-condition. There is thus obtained the decimal result, namely, the number 49 in the form of marked cores respectively in two of the twenty reading amplifiers Vst, representing the second information.

The next timing impulse effects closure of the switch S0122. The reading outof the cores of the reading amplifier, each of which cores carries a base winding of a switching transistor, form a circuit extending over the switch S0112, the blocking wire B12, and one respective switching transistor of a reading amplifier group and the writing wires assigned thereto. These two writing wires convert the decimal result in the encoder C0 (FIG. 5) into a code, for example, the 2- from fi-element code, from which the message is extended, for example, to the printing mechanism ED (FIG. 5) for actuating the printing magnet thereof. The message or mail man number is now printed on the involved postal item which is thereafter routed to the proper receptacle.

However, if the address noted on a postal item indicates a street along which mail is delivered by two or more mail men, it will be necessary to include in the keying of the input information the house number, so as to determine the proper mail man. The address Bahnhofsplatz No. 7 shall serve as an encoding example. The four characteristic characters selected from the address are the characters BHNP. it is assumed that the mail for this location is delivered by two mail men and that one of the respective delivery areas, including the house numbers 1 and 7, is designated by the number 04, while the other delivery area, including the house numbers 5 and 6, is designated by the number 05.

The encoding operation starts in this case again with keying the characters BHNP into the series-parallel converter. The information stored in the converter is simultaneously read out, again making four switching transistors conductive, such transistors being with the aid of their writing wires, the blocking wire and the switch Schl (FIG. 2) effective to change in the character encoding field the magnetization of the magnetic core assigned to the character combination, to place such core into the 1-condition.

Upon reading out the character encoding field, one of the marked cores will upon change of magnetization into the O-condition deliver reading voltages to its two reading wires, which voltages are conducted to the reading amplifiers. The reading amplifiers comprise, as noted before, an amplifying stage as well as a core-transistor combination connected thereto, the magnetization of the core of which is changed to the l-condition responsive to receipt of a reading signal at the amplifier input. Proceeding in accordance with the previously explained case, the stored information would be released again responsive to the next timing pulse, making the switching transistors, assigned to the storage core conductive, thereby activating two writing wires in the encoding field or board so as to effect the release of the result.

In the case which is now being considered, with release of information from the amplifiers is suppressed by a control impulse. The control impulse is produced by the provision of an auxiliary reading wire on all cores in the character encoding held, the character combination of which, which is assigned thereto, cannot form a definite and unequivocal result without an additional house number fed into the equipment. All these reading wires are serially related and are extended to a control reading amplifier. The output impulse from this control amplifier effects the three following operations, namely (a) a signal is given to the coding desk or position which signifies a demand for a house number input; (b) the release of information contained in the reading amplifiers is prevented, such information representing an intermediate result which was arbitrarily assumed to include two numbers; and (c) the series-parallel converter is prepared for the receipt of the house number input. The switch Sch3 (MG. 2) is closed. The electronic stepping device is brought from the initial position into the first operating position (FIG. 1), in which the switch S1 is opened and switch S2 is closed. This is necessary in order to permit using the same series-parallel converter for the receipt of house numbers. The house number is in the assumed example always fed in as a three place number, thus making it possible to release without actuation of a start key the encoding operation automatically after keying the third number. in the event that the house number consists of a single digit or of a two digit number, two zeroes or one zero must respectively be added to complete the three places.

The lO -number of the house number is according to time identical current. vmagnetization to the l-condition while the core its quantum fed into one of the first ten columns of the second row or line of the converter (H6. 1). The Pil -number or digit of the house number is stored in the third row and the lO -number or digit reaches with the aid of the stepping device the fourth row.

The writing operation is released when one core in the second, third and fourth row of the series-parallel converted is marked and when the intermediate result has been stored in two cores of the reading amplifier. All of the cores of the converter as well as the cores of the 10 and l0-reading amplifier groups are now read out. The transistors, the cores of which contained the message 1 now become conductive owing to the action of the base winding on each core respectively assigned to a switching transistor and the voltage produced in the respective base windings upon change of magnetization of the corresponding cores. A circuit is produced (FIG. 2) which extends over the switch Sch3 and three switching transistors of the converter which are characteristic of the supplied house number, and over the writing wires 6 and the blocking wires B21 and E12 as well as over two switching transistors of the reading amplifiers and their writing wires 7 to the negative terminal of the current source. The activated writing wires 7 are thereby characteristic for the intermediate result. These five +3- term-s (35+2 act jointly, with a term operating with -41, on the blocking wire B12 (FIG. 4) of all cores of the number encoding field. Only one core ill of the number encoding field, to which are assigned all five terms in the form of writing currents, is changed in magnetization to the 1-condition.

It shall be assumed that the intermediate result 42 was formed with the aid of the combination Bill P. This means, that the core of the reading amplifier with the order 4x10 and also the amplifier wtih the order 2x10 contain the message l." The house number G07 was thereafter fed to the converter. Upon simultaneous readout of the cores of the converter and of the reading amplifier, five switching transistors will become conductive by the action of the encoding field writing wires 521, set, 5&3 as well as 4 and all. They jointly affect in the number coding field, the core Kill (FIG. 4) and four of these writing wires affect, for example, the core K116. The core Kllltl represents with its two reading wires the result 04 while the core Kill represents the result 05. Which of the two cores is now magnetized into the 1-condition will depend upon the writing wires s which had been determined by the digits of the house number while the writing wire ydetermined by the intermediate result-have predetermined the cores K116 and K111 from a multitude of cores of the number encoding field. In the assumed example, the house number O07 activated the wires 621 (number 0.18 Bali (number 0.10 and 663 (number 7.10 According to FIG. 2, all writing wires are serially related, including the blocking wire B12, and therefore carry at the same The core Kill is changed in Kilt; remains in the O-condition. This effects the elimination, and upon readout of the number encoding field, the core K111 is again placed into the 0-condition, whereby the voltage occurring in the reading wires triggers the reading amplifiers 0x10 and 5X1? The switch S0122 (PEG. 2) is closed incident to the next timing pulse. The result formation is effected as already described, by reading out the cores of the reading amplifier.

The writing wires 5 of the converter extend through the character encoder as well as through the number encoder. The blocking wires are likewise disposed in serial relationship. A maximum of four writing wires can be activated in the character encoding during the writing operation, which may lead in the character encoding field, with the blocking wire B11 which is effective with 3J, to a change of magnetization of a core into the l-condition. In the number encoding field there act this inaromas j stant at a maximum only three of the four activated writing wires, since no w-ire extends from the first row of the converter (PEG. 2) into the number encoding field, because there is no house number with a l -digit. No feedingdn can occur during the character encoding in the number encoding field, since the blocking wire B12 in the number encoder is effective with -43.

0n the other hand, a feeding-in operation cannot occur in a number encoding operation in the cores of the character encoding feld, because there are in such case only three activated writing wires each carrying +11 which reach the encoding field from blocking .wire B/1 acting with -31 on all cores of the character encoding field prevents a feedingin. However, in the number or di it encoding field, there must be considered in addition to the 3 X (+117) 2X (+117) from the writing wires of the switching transistors of the reading amplifier so that the blocking wire BIZ which is active with M can not prevent the feeding-in in one core.

Accordingly, all reading wires of both encoding fields can be serially connected with the san e digit of a tens power and extended to a common amplifer with 1-bit storer and SW1 .ching transistor connected thereto.

Upon considering the writing circuits formed in the respective working phases (PEG. 5), it will be seen that the circuit in the character encoding extends from the point 1 over the series-parallel converter SFU, the character encoding field 1214C and the number encoding field ZiC, with its writing and blocking wires, over the switch S0111 to the point H.

In the number encoding, the current from the point I also reaches the point 111 over the series-parallel converter SPU, the characterand the digit-encoding fields BuC, ZiC and the two amplifier groups Vst and 10Vst, with their writing wires, and for the encoding field C0. The encoding field is during this phase blocked by an activated blocking wire which affects all cores of this encoding field so that the intermediate result cannot be fed in.

When the decimal result is given off to the encoding device, the current will be conducted from the point 1V over the switch ScltZ to the blocking wire BIZ of the digit encoding field and from there over the amplifier groups to the point ill. The switching in of the blocking Wire B12 is necessary since the writing wires or" the reading amplifier extend into the encoding field and also to the intermediate result release in the digit encoding field. The blocking wire B22 prevents in the final result release a feeding-in to the digit encoding field.

Changes may be made within the scope and spirit of the appended claims which define what is believed to be new and desired to have protected by Letters Patent.

1 claim:

1. A circuit arrangement for converting a first information which is represented by the activation respectively of one of in elements in x groups, whereby in may vary from group to group, into a second information which is represented by the magnetization of one of n magnet cores di posed in a field of cores having wires extending therethrough, a plurality of said wires passing through the respective cores, comprising means forming x stages corresponding to the x groups, each stage comprising switches connected in parallel relationship, said switches provided respectively with serially disposed writing wires, the switches of the respective stages being respectively assianed to the in elements of the corresponding group of the converter, so that the the first information and being operatively closed upon activation of the corresponding element, the series circuit of said stages being disposed in series with a blocking wire extending through all cores, said blocking wire passing (as--11) times through each core in a direction opposite to the direction of the writing wires, whereby an individual current circuit is formed responsive to closure of a switch, which circuit extends over x writing wires and the blocking wire, said individual circuit passing x-times only through one of the n cores and being owing to o posing energization effected by said blocking wires operative to change the magnetization of only such core to which is assigned the second information.

2. A circuit arrangement according to claim 1, wherein ransistors constitute said switches.

3. A circuit arrangement according to claim 1, comprising'an auxiliary sensing wire provided for each maget core assigned to the second information, which core has no definite result assigned thereto, a signal therefrom signifying that an additional information item is required.

4. A circuit arrangement according to claim 1, wherein x groups of a first information form in a first core arrangement a second information, identical x groups being combined with k further groups to form, as a third information, in a second core arrangement a fourth information, said two core arrangements distinguishing from one another by premagnetization of different strength.

5. A circuit arrangement according to claim 1, wherein each magnet core which represents the second information has assigned thereto the following wires, namely, x writing wires, a blocking wire acting on such core only at the writing instant with (xll)3 change of magnetization current, a readout wire, and a reading wire.

6. I A circuit arrangement according to claim 5, wherein the sensing wires for terms of identical magnitude are serially connected and conducted to sensing amplifiers comprising respectively an amplifier stage and a coretransistor combination connected therewith.

7. A circuit arrangement according to claim 6, comprising an encoder, the writing wires of said sensing amplifier group being efiective to convert in said encoder the final result to form a predetermined code, and a printer for receiving said code.

d. A circuit arrangement according to claim 1, comprising an auxiliary sensing wire provided for each magnet core assigned to the second information, which core has no definite result assigned thereto, said auxiliary sensing wires being serially disposed and conducted to a controlsensing amplifier, the output impulse of said control-sensing amplifier indicating, first, a request for the input of supplemental information, second, causing storage of the present information, and, third, preparing the circuit'arrangement for the receipt or" a supplemental criterion for completing the present intermediate result.

Reterences Cited by the Examiner UNITED STATES PATENTS MALCOLM A. MORRISON, Primary Examiner. 

1. A CIRCUIT ARRANGEMENT FOR CONVERTING A FIRST INFORMATION WHICH IS REPRESENTED BY THE ACTIVATION RESPECTIVELY OF ONE OF M ELEMENTS IN X GROUPS, WHEREBY M MAY VARY FROM GROUP TO GROUP, INTO A SECOND INFORMATION WHICH IS REPRESENTED BY THE MAGNETIZATION OF ONE OF N MAGNET CORES DISPOSED IN A FIELD OF CORES HAVING WIRES EXTENDING THERERESPECTIVE CORES, COMPRISING MEANS FORMING X STAGES CORREREPECTIVE CORES, COMPRISING MEANS FORMING X STAGES CORRESPONDING TO THE X GROUPS, EACH STAGE COMPRISING SWITCHES CONNECTED IN PARALLEL RELATIONSHIP, SAID SWITCHES PROVIDED RESPECTIVELY WITH SERIALLY DISPOSED WRITING WIRES, THE SWITCHES OF THE RESPECTIVE STAGES BEING RESPECTIVELY ASSIGNED TO THE M ELEMENTS OF THE CORRESPONDING GROUP OF THE FIRST INFORMATION AND BEING OPERAIVELY CLOSED UPON ACTIVATION OF THE CORRESPOONDING ELEMENT, THE SERIES CIRCUIT OF SAID STAGES BEING DISPOSED IN SERIES WITH A BLOCKING WIRES EXTENDING THROUGH ALL CORES, SAID BLOCKING WIRE PASSING (X-1) TIMES THROUGH EACH CORE IN A DIRECTION OPPOSITE TO THE DIRECTION OF THE WRITING WIRES, WHEREBY AN INDIVIDUAL CURRENT CIRCUIT IS FORMED RESPONSIVE TO CLOSURE OF A SWITCH, WHICH CIRCUIT EXTENDS OVER X WRITING WIRES AND THE BLOCKING WIRE, SAID INDIVIDUAL CIRCUIT PASSING X-TIMES ONLY THROUGH ONE OF THE N CORES AND BEING OWING TO OPPOSING ENERGIZATION EFFECTED BY SAID BLOCKING WIRES OPERATIVE TO CHANGE THE MAGNETIZATION OF ONLY SUCH CORE TO WHICH IS ASSIGNED THE SECOND INFORMATION. 